Some thoughts on ASR and the reviews


I’ve briefly taken a look at some online reviews for budget Tekton speakers from ASR and Youtube. Both are based on Klippel quasi-anechoic measurements to achieve "in-room" simulations.

As an amateur speaker designer, and lover of graphs and data I have some thoughts. I mostly hope this helps the entire A’gon community get a little more perspective into how a speaker builder would think about the data.

Of course, I’ve only skimmed the data I’ve seen, I’m no expert, and have no eyes or ears on actual Tekton speakers. Please take this as purely an academic exercise based on limited and incomplete knowledge.

1. Speaker pricing.

One ASR review spends an amazing amount of time and effort analyzing the ~$800 US Tekton M-Lore. That price compares very favorably with a full Seas A26 kit from Madisound, around $1,700. I mean, not sure these inexpensive speakers deserve quite the nit-picking done here.

2. Measuring mid-woofers is hard.

The standard practice for analyzing speakers is called "quasi-anechoic." That is, we pretend to do so in a room free of reflections or boundaries. You do this with very close measurements (within 1/2") of the components, blended together. There are a couple of ways this can be incomplete though.

a - Midwoofers measure much worse this way than in a truly anechoic room. The 7" Scanspeak Revelators are good examples of this. The close mic response is deceptively bad but the 1m in-room measurements smooth out a lot of problems. If you took the close-mic measurements (as seen in the spec sheet) as correct you’d make the wrong crossover.

b - Baffle step - As popularized and researched by the late, great Jeff Bagby, the effects of the baffle on the output need to be included in any whole speaker/room simulation, which of course also means the speaker should have this built in when it is not a near-wall speaker. I don’t know enough about the Klippel simulation, but if this is not included you’ll get a bass-lite expereinced compared to real life. The effects of baffle compensation is to have more bass, but an overall lower sensitivity rating.

For both of those reasons, an actual in-room measurement is critical to assessing actual speaker behavior. We may not all have the same room, but this is a great way to see the actual mid-woofer response as well as the effects of any baffle step compensation.

Looking at the quasi anechoic measurements done by ASR and Erin it _seems_ that these speakers are not compensated, which may be OK if close-wall placement is expected.

In either event, you really want to see the actual in-room response, not just the simulated response before passing judgement. If I had to critique based strictly on the measurements and simulations, I’d 100% wonder if a better design wouldn’t be to trade sensitivity for more bass, and the in-room response would tell me that.

3. Crossover point and dispersion

One of the most important choices a speaker designer has is picking the -3 or -6 dB point for the high and low pass filters. A lot of things have to be balanced and traded off, including cost of crossover parts.

Both of the reviews, above, seem to imply a crossover point that is too high for a smooth transition from the woofer to the tweeters. No speaker can avoid rolling off the treble as you go off-axis, but the best at this do so very evenly. This gives the best off-axis performance and offers up great imaging and wide sweet spots. You’d think this was a budget speaker problem, but it is not. Look at reviews for B&W’s D series speakers, and many Focal models as examples of expensive, well received speakers that don’t excel at this.

Speakers which DO typically excel here include Revel and Magico. This is by no means a story that you should buy Revel because B&W sucks, at all. Buy what you like. I’m just pointing out that this limited dispersion problem is not at all unique to Tekton. And in fact many other Tekton speakers don’t suffer this particular set of challenges.

In the case of the M-Lore, the tweeter has really amazingly good dynamic range. If I was the designer I’d definitely want to ask if I could lower the crossover 1 kHz, which would give up a little power handling but improve the off-axis response.  One big reason not to is crossover costs.  I may have to add more parts to flatten the tweeter response well enough to extend it's useful range.  In other words, a higher crossover point may hide tweeter deficiencies.  Again, Tekton is NOT alone if they did this calculus.

I’ve probably made a lot of omissions here, but I hope this helps readers think about speaker performance and costs in a more complete manner. The listening tests always matter more than the measurements, so finding reviewers with trustworthy ears is really more important than taste-makers who let the tools, which may not be properly used, judge the experience.

erik_squires

@amir_asr “Please point out in the link where it says audio measurements are not able to keep up with the human ear:

  • nice to hear from you once again, amir. Here we go, highlighted in bold below -

@kevn 

There is absolutely nothing in there about audio measurements in general, or it being worse than the human hearing.  You have cut and paste unrelated things.

As i have explained, many audio measurements are done without any Fourier analysis.  SINAD, SNR, THD+N vs frequency, frequency response, etc. are all done simply by measuring voltages and levels.  No transform of any kind.

When we do use Fourier transform in measurements, we can choose any length and arrive at frequency resolution far better than human hearing.  When doing so, we are not at all interested in timing as the input is constant.

As @markwd has properly explained, the main usefulness of this study is in developing models of human hearing and how they need to take into account its non-linearity in this regard. It is not in any way, shape or form about the usefulness of audio equipment measurements.

I explained all of this in detail before. Please don't keep repeating the same thing by copying stuff from the article, which by the way, is NOT the paper itself.

I, for one, would love to read one day about your having invented a measuring machine that exceeds the Fourier uncertainty principle.

A "measuring machine" can be built to mimic human hearing and produce the same results as that study.  But this has nothing to do with measuring audio equipment.  There, we are not trying to analyze human hearing but the transparency of a piece of equipment. 

The audio equipment is NOT attempting to analyze what it is hearing.  Nor is its measurements.  As such, none of this study applies to analysis of audio gear, or its measurements.

There is only one specific case in audio where we want to show both timing and frequency.  That is the waterfall/CSD plot.  I include that in every one of my speaker measurements.  Take this review of Genelec 8361A (a superb studio monitor):

 

Notice how the frequency and time are presented at the same time.  Depending on the number of points used, we can make either X axis higher resolution, or Y, or balance the two.  Depending on what phenomenon we are are interested in, we optimize one or the other.  As a general rule, I highly recommend people to not look at this specific measurement as it can vary that way.

Outside of this one example (whose information you can extract from others), there are no other audio measurements where we are trying to simultaneously look at time and frequency resolution.  It is always the latter that we care about meaning we can highly optimize for frequency resolution, blowing away human acuity by a mile.  Look at the review of this Schiit Vidar 2 Amplifier:

And this multitone test that uses FFT:

Your ear has no prayer of hearing those tine spikes.  It simply hears them as background noise, reducing practical dynamic range.  This is because I have used whopping 256,000 points to make that measurement allowing incredible resolution that is able to show those spikes.  The test signal keeps repeating so we don't care about its timing. 

 

It is also beyond argument that human hearing can exceed the Fourier limit of uncertainty, at times by a factor of ten.

BTW, the person who did that is a musician.  As a rule, musicians are not audiophiles.  My piano teacher wouldn't know a tweeter from a woofer.  If this study applied to audio reproduction, then all musicians would have been diehard audiophiles but they are not.

Musicians are also better at hearing room reflections than general population.  Again, that doesn't make them want to buy fancy audio systems.  

@amir_asr  

bummer, you chose the second. Trust me, it will come back to haunt you.

In disappointment - kevin